Method of modifying a worksite

ABSTRACT

A method is disclosed of modifying a worksite for calibrating a vehicle model used to autonomously control a first machine on the worksite. The method may include receiving a signal from the first machine indicative of an aspect of the vehicle model in need of calibration. The method may also include determining, in response to receipt of the signal, that the worksite includes a calibration site having a characteristic corresponding to the aspect of the vehicle model, and that calibrating the aspect of the vehicle model requires modifying the characteristic of the calibration site. The method may further include autonomously modifying the characteristic of the calibration site with a second machine at the worksite, and directing the first machine to the modified calibration site for autonomous calibration of the aspect of the vehicle model.

TECHNICAL FIELD

The present disclosure relates generally to a method of managing aworksite and, more particularly, to a method of modifying a worksite forvehicle calibration.

BACKGROUND

Autonomous worksites are designed to provide productivity gains throughmore consistency in processes. Such worksites may employ a plurality ofautonomous machines such as, for example, off-highway haul trucks, motorgraders, and other types of heavy equipment to perform a variety oftasks. Primary operation of such machines may be controlled by acombination of on-board and off-board computers, processors, and otherelectronic controllers rather than human operators. As a result,autonomous operation may enhance the productivity of the machines, andreduce the human resources required for controlling the operation of theworksite.

To operate the autonomous machines safely and efficiently on theworksite, the machines are usually equipped with sensors for detectingobjects on the worksite. For example, RADAR (radio detection andranging) sensors, SONAR (sound navigation and ranging) sensors, LIDAR(light detection and ranging) sensors, IR (infrared) and non-IR cameras,and other similar sensors may be used. The sensed objects may includespecific geographical features of the worksite (for example, berms,markers, rocks, etc.), the other machines on the worksite, and anyobstructions on the worksite. The machines are also generally equippedwith sensors for detecting information regarding characteristics of themachine itself (for example, engine speed, travel and/or work speed,steering angle, transmission gear or gear ratio, orientation such aspitch and roll, geographical location, load weight, and loaddistribution). A vehicle model, which is a computer model that is usedin autonomous operation of the machine on the worksite, may be stored ina computer memory of the machine. Processors on-board the machine mayreceive outputs from the sensors and, using the vehicle model, maypredict how the machine will operate, for example, given its currentspeed and steering angle, and/or future drive commands of the machine.In the event the processors predict that the machine should not continueon its current course (for example, the processors predict the machinewill collide with a sensed object if the machine maintains its currentsteering angle), the processors may also use the vehicle model todetermine what changes should be made, and to predict whether thesechanges will, in fact, result in continued safe and efficient operationof the machine.

Periodic calibration of the vehicle model is necessary for desiredmachine operation since the predicted performance of the autonomousmachine may vary substantially from the actual performance of themachine. For example, calibration may be required due to, among otherthings, a change in worksite conditions, a change in the configurationof the machine, and/or because of wear of components used in themachine.

To perform calibration of the vehicle model, the autonomous machine mayundergo a series of specific tests. The tests measure the actualperformance of the machine, using the uncalibrated vehicle model, undera variety of conditions, including different loads, speeds, steeringangles, and orientations of the machine. After the conclusion of thetesting, the actual performance of the machine under the variousconditions is compared to the performance that was predicted by theuncalibrated vehicle model under those same conditions. The vehiclemodel may then be adjusted or calibrated based on the comparison, sothat future use of the calibrated vehicle model will result in theactual operation of the autonomous machine being substantially the sameas the predicted operation of the machine.

An exemplary calibration system and method is described in U.S. PatentPublication No. 2006/0164295 (the '295 publication) by Focke et al.published on Jul. 27, 2006. Specifically, the '295 publication describesa system for simultaneous calibration of two different types of sensors,for example, an image sensor and a radar sensor mounted on a motorvehicle. During calibration of the two sensors, the motor vehicle isaligned in front of a calibration object in such a way that the imageand radar sensors detect reference features of the calibration objectand responsively create calibration data. The calibration data is useddirectly for calibration of the participating sensors. For example, thecalibration data is used for automatic correction of a deviation of asensor axis in relation to a vehicle longitudinal axis or by anautomotive technician for mechanical adjustment of sensor placement.These procedures are possible during manufacture or repair of the motorvehicle.

Although the sensor system of the '295 publication may be helpful incalibrating machine-mounted sensors, the benefit may be limited as thereare a number of different types of vehicle model calibration that may benecessary in order for an autonomous work machine to operateefficiently. For example, different loads, speeds, steering angles, andorientations of the machine may all be parameters that requirecalibration and/or recalibration during the lifetime of the autonomousmachine.

Challenges to calibrating an autonomous work machine vehicle model mayinclude, for example, the need for an autonomous machine to betransported to an area designated specifically for calibration-relatedactivity. The designated area may be a significant distance from theautonomous worksite. The size of the designated area may limit thenumber of machines undergoing vehicle model calibration at anyparticular time. Further, it may take a significant amount of time tocomplete all of the specific tests required for complete calibration ofthe vehicle model. Thus, the autonomous machine may not be available toperform any task on the autonomous worksite for a relatively long periodof time, until the vehicle model is completely calibrated and theautonomous machine is transported to the worksite. Subsequentrecalibration of the vehicle model may result in similar disadvantages,since it may be necessary to transport the autonomous machine back tothe designated area to again undergo the series of specific tests.

The disclosed systems and methods are directed to overcoming one or moreof the problems set forth above and/or other problems of the prior art.

SUMMARY

The disclosure may provide a method of modifying a worksite forcalibrating a vehicle model used to autonomously control a first machineon the worksite. The method may include receiving a signal from thefirst machine indicative of an aspect of the vehicle model in need ofcalibration. The method may also include determining, in response toreceipt of the signal, that the worksite includes a calibration sitehaving a characteristic corresponding to the aspect of the vehiclemodel, and that calibrating the aspect of the vehicle model requiresmodifying the characteristic of the calibration site. The method mayfurther include autonomously modifying the characteristic of thecalibration site with a second machine at the worksite, and directingthe first machine to the modified calibration site for autonomouscalibration of the aspect of the vehicle model.

The disclosure may further provide a method of modifying a worksite forcalibrating a vehicle model used to autonomously control a first machineon the worksite. The method may include determining, with a controllerassociated with the machine, that an aspect of the vehicle model is inneed of calibration. The method may include providing a signal,indicating that the aspect is in need of calibration, from thecontroller to a worksite management system disposed remote from thefirst machine. The method may also include determining, with theworksite management system, that the worksite includes a calibrationsite having a characteristic corresponding to the aspect of the vehiclemodel, and that calibrating the aspect of the vehicle model requiresmodifying the characteristic of the calibration site. The method mayalso include directing, with the worksite management system, a secondmachine at the worksite to autonomously modify the characteristic of thecalibration site. The method may further include directing, with theworksite management system, the first machine to the modifiedcalibration site for autonomous calibration of the aspect of the vehiclemodel.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a pictorial illustration of an autonomous machine having anexemplary disclosed vehicle model calibration system;

FIG. 2 is a pictorial illustration of an exemplary worksite managementsystem coordinating the creation of an exemplary calibration path forthe machine of FIG. 1;

FIG. 3 is a flow chart illustrating an exemplary worksite managementsystem operation performed for the machine of FIG. 1;

FIG. 4 is a flow chart illustrating an alternate exemplary worksitemanagement system operation performed for the machine of FIG. 1; and

FIG. 5 is a pictorial illustration of an exemplary worksite mapgenerated by the worksite management system.

DETAILED DESCRIPTION

FIG. 1 illustrates a machine 10 having an exemplary vehicle modelcalibration system 12 that may calibrate and/or recalibrate a vehiclemodel used to autonomously control machine 10 on a worksite 11 (FIG. 2).Worksite 11 may include, for example, a mine site, a landfill, a quarry,a construction site, or any other type of worksite known in the art.

Machine 10 may embody an autonomous mobile machine. An “autonomous”machine refers to an unmanned machine that includes on-board and/oroff-board computers, processors, and/or other electronic controllerswhich, based on input from various machine sensors, stored data, andcontrol algorithms, provides outputs to control various machine systemssuch as steering, braking and propulsion to accomplish desired tasks.For example, an autonomous haul truck may include on-board systems thatdetermine the position and heading of the machine, and control steering,propulsion, and braking to follow a route provided by an off-board pathplanning system and to avoid obstacles in the machine's path.Semi-autonomous machines may provide some functions that are controlledby the on-board and off-board systems, while allowing an operator tocontrol other functions. For example, for a motor grader, the on-boardcontroller may control the machine to follow a route, while the operatorcontrols the implement or blade. Machine 10 may include, for example, anearth moving machine such as an off-highway haul truck, a wheel loader,a motor grader, a fluid delivery truck, or any other mobile machineknown in the art. Machine 10 may further include, among other things, apower source 15, and a body 14 supported by one or more traction devices16.

Power source 15 may include an engine such as, for example, a dieselengine, a gasoline engine, a gaseous fuel powered engine such as anatural gas engine, or any other type of engine apparent to one skilledin the art. Power source 15 may alternatively include a non-combustionsource of power such as a fuel cell, a power storage device, an electricmotor, or other similar mechanism. Power source 15 may be connected totraction devices 16 via a direct mechanical coupling, an electriccircuit, a hydraulic circuit, or in any other suitable manner.

On-board controller 20 may cause machine 10 to autonomously follow aroute generated by a path planner associated with worksite 11. Machine10 may also include a semi-autonomous or non-autonomous mobile machine.In such cases, a semi-autonomous or non-autonomous machine 10 mayreceive, from a path planner associated with worksite 11, recommendedroutes for an operator of machine 10 to consider. The recommended routesmay be presented to the operator via a monitor or other electronicdisplay. The operator of a semi-autonomous or non-autonomous machine 10may evaluate the recommended options presented by the path plannerassociated with worksite 11 and select a desirable route for machine 10to follow. A path planner associated with worksite 11 may include aworksite management system 38 which may generate a calibration plan or“calibration roadmap” designating a recommended calibration route 580(FIG. 5) by which machine 10 may efficiently visit one or morecalibration sites 40 within worksite 11 while circumventing calibrationexcluded (or exclusion) zones 550 (FIG. 5). A calibration exclusion zone550 may be an area within worksite 11 that is excluded by worksitemanagement system 38 for purposes of calibration. Calibration sites 40may include road segments within worksite 11 that are adequate forcalibration of an aspect of a vehicle model associated with machine 10.Calibration exclusion zones 550 may include road segments on worksite 11which may include high traffic areas, for example, an intersection or aloading and/or dumping zone. Recommended calibration route 580,calibration sites 40, and calibration exclusion zones 550 will bediscussed in greater detail below.

Machine 10 may safely and efficiently autonomously follow recommendedcalibration routes 580 by relying on data input from one or more sensors18. As shown in FIG. 1, sensors 18 may be mounted to body 14 and may beused for object detection. The objects detected by sensors 18 mayinclude specific areas on worksite 11, for example, areas at whichmaterial is loaded and unloaded, geographical features of worksite 11,other autonomous or human-operator-controlled machines on the worksite,and any obstructions on the worksite. In an exemplary embodiment,machine 10 may be equipped with one or more short range sensors 18S,medium range sensors 18M, and/or long range sensors 18L located atdifferent positions around body 14 of machine 10. Each of sensors 18 (S,M, L) may embody a device that detects the position, configuration,shape, and/or orientation of objects disposed within a sensing range ofthe sensors 18 (S, M, L). One or more sensors 18 (S, M, L) may include aLIDAR device, a RADAR device, a SONAR device, an IR or non-IR cameradevice, and/or any other sensing device known in the art. In onepossible example, sensors 18 (S, M, L) may include an emitter that emitsa detection beam and an associated receiver that receives a reflectionof that detection beam. Based on characteristics of the reflected beam,a distance and a direction from an actual sensing location of sensors 18(S, M, L) on machine 10 to a portion of the sensed object may bedetermined. Sensors 18 (S, M, L) may then generate a position signalcorresponding to the distance and direction, and communicate theposition signal to on-board controller 20. On-board controller 20 mayreceive the position signal from sensors 18 (S, M, L) and, using acalibrated vehicle model, may operate machine 10 to avoid a collisionwith the sensed object. For example, on-board controller 20 may steermachine 10 to the left or right to avoid an object that is detected bysensors 18 (S, M, L).

Machine 10 may also be equipped with one or more sensors 22, mounted atdifferent locations on machine 10, for detecting information regardingone or more conditions of the machine 10, such as a load carried bymachine 10, a maintenance state of machine 10, and/or a location ofmachine 10. In an exemplary embodiment, sensors 22 may include one ormore of a speed sensor 24, a steering angle sensor 26, a load weightsensor 28, a load distribution sensor 30, an orientation sensor 32, anda location and heading sensor 34.

Speed sensor 24 may detect an actual ground or travel speed of machine10 as it moves on worksite 11. The speed of machine 10 may be detectedin a variety of ways. For example, speed sensor 24 may detect a numberof revolutions over a given time period for a component of a tractiondevice 16, such as a wheel hub, and either speed sensor 24, on-boardcontroller 20, or another processor may determine the speed of machine10 using this information. In another embodiment, speed sensor 24 maymeasure an actual distance traveled by machine 10 over a given timeperiod, and either speed sensor 24, on-board controller 20, or anotherprocessor may determine the speed of machine 10 based on thisinformation. Speed sensor 24 is not limited to a specific location onmachine 10, however, and is not limited in the way that it detects thespeed of machine 10.

Steering angle sensor 26 may detect an actual steering angle of machine10. The steering angle may be detected in a variety of ways. Forexample, steering angle sensor 26 may sense a location, angle, and/orother characteristic of a component of a traction device 16, such as awheel hub. In another embodiment, steering angle sensor 26 may sense alocation, angle, and/or other characteristic of another component ofmachine 10, such as a rack and/or a pinion when machine 10 is turned bya rack-and-pinion steering system. In that case, a rotation angle of thepinion and/or a translation of the rack may be sensed, and eithersteering angle sensor 26, on-board controller 20, or another processormay determine the steering angle of machine 10 using this information.Steering angle sensor 26 is not limited to a specific location onmachine 10, however, and is not limited in the way that it detects thesteering angle of machine 10.

Load weight sensor 28 may detect an actual weight of material beinghauled by machine 10, in the event machine 10 is configured to haulmaterial on worksite 11. The weight of the load carried by machine 10may be detected in a variety of ways. For example, load weight sensor 28may measure decreases in effective lengths of one or more springssupporting a dump box 36 of machine 10, and either load weight sensor28, on-board controller 20, or another processor may determine theweight of material hauled by machine 10 using this information. Loadweight sensor 28 is not limited to a specific location on machine 10,however, and is not limited in the way that it detects the weight ofmaterial being hauled by machine 10.

Load distribution sensor 30 may detect an actual distribution of theweight of the material being hauled by machine 10. The distribution ofthe weight hauled by machine 10 may be detected in a variety of ways.For example, load distribution sensor 30 may measure decreases ineffective lengths between or among groups of springs supporting dump box36 of machine 10. By comparing lengths of springs on the front of dumpbox 36 to lengths of springs on the back of dump box 36, and/or tolengths of springs on the left or right side of dump box 36, either loaddistribution sensor 30, on-board controller 20, or another processor maydetermine the distribution of the weight of the material hauled bymachine 10 based on such comparisons. Load distribution sensor 30 is notlimited to a specific location on machine 10, however, and is notlimited in the way that it detects the distribution of weight ofmaterial being hauled by machine 10.

Orientation sensor 32 may determine an actual orientation of machine 10on worksite 11. The orientation of machine 10 may include a roll ofmachine 10, which may be an angle measured about a roll axis thatextends generally between a front and a back of machine 10, and/or mayinclude a pitch of machine 10, which may be an angle measured about apitch axis that extends generally between left and right sides ofmachine 10. Orientation sensor 32 may directly detect the orientation ofmachine 10 (e.g., detect the orientation of machine 10 relative to anartificial horizon), or may detect the orientation of an area on theground that supports machine 10. Either orientation sensor 32, on-boardcontroller 20, or another processor may determine the orientation ofmachine 10 using this information. Orientation sensor 32 is not limitedto a specific location on machine 10, however, and is not limited in theway that it detects the orientation of machine 10.

Location and heading sensor 34 may determine an actual geographicallocation and/or an actual heading of machine 10 on worksite 11. Thelocation and heading of machine 10 may be detected in a variety of ways.For example, sensor 34 may utilize a positioning system, to determinevarious operating parameters of the machine such as velocity, pitchrate, yaw rate, roll rate, etc. The positioning system may utilizeGlobal Positioning System (GPS) data along with data from an InertialMeasurement Unit (IMU), which typically includes one or more yaw ratesensors such as gyroscopes, to calculate heading. In another embodiment,sensor 34 may include a local position detecting system that indicatesthe geographical location and/or heading of machine 10 relative to oneor more transmitters on the worksite 11. Either sensor 34, on-boardcontroller 20, or another processor may determine the location ofmachine 10 and/or the actual heading of machine 10 based on thisinformation. Sensor 34 is not limited to a specific location on machine10, however, and is not limited in the way that it detects the locationof machine 10.

The above-described sensors 22 may generate signals corresponding to thedetected conditions of machine 10, and may communicate the signals toon-board controller 20. On-board controller 20 may receive the signalsfrom sensors 22 and enter information carried by one or more of thesignals into, for example, a memory, a look-up table, a control map,and/or a control algorithm within machine 10 to maintain safe andefficient operation of machine 10 on worksite 11.

On-board controller 20 may include components configured to monitor,record, condition, store, index, process, and/or communicate informationreceived from sensors 18 and sensors 22. These components may include,for example, a memory, one or more data storage devices, one or moreprocessors or central processing units, and/or any other components,including tangible, physical, and non-transitory components (hardwareand software), which may be used to run the disclosed application.Furthermore, although aspects of the present disclosure may be describedgenerally as being stored within a controller memory, one skilled in theart will appreciate that these aspects can be stored on or read fromdifferent types of computer program products or non-transitory andtangible computer-readable media such as computer chips and secondarystorage devices, including hard disks, floppy disks, optical media,CD-ROM, or other forms of RAM or ROM. On-board controller 20 maycommunicate with, receive information and/or instructions from, orotherwise be controlled by an automated worksite management system 38(FIG. 2), such as Caterpillar Inc.'s MINESTAR SYSTEM™ or other similarsystems.

Worksite management system 38 may include components configured tomonitor, record, condition, store, index, process, and/or communicateinformation received from sensors 18, sensors 22, and/or on-boardcontroller 20 of all machines 10 at worksite 11. These components mayinclude, for example, a memory, one or more data storage devices, one ormore processors or central processing units, or any other components,including tangible, physical, and non-transitory (hardware and software)components, which may be used to run the disclosed application.

In exemplary embodiments, worksite management system 38 may be incommunication with multiple machines 10 and may track respectiveservice-related needs of one or more machines 10. Any of the data storedby worksite management system 38 may be retrieved and addressed whenmachine 10 frequents a service center. Such service-related needs mayinclude, for example, tire air pressure, status of tire treads and/orbrake conditions. Worksite management system 38 may also record the timeof recordation of the various service-related needs. Additionally,worksite management system 38 may schedule routine maintenance formachine 10 and/or may coordinate the repair and maintenance of machine10 as problems arise.

In addition to service-related needs, worksite management system 38 mayalso monitor and address calibration-related needs for machine 10.Calibration-related needs may exist for machine 10 when machine 10 isnew and/or after machine 10 has been in use for any particular amount oftime. Initially, the vehicle model stored in a computer memoryaccessible by on-board controller 20 of machine 10 may be uncalibrated.If a vehicle model has been calibrated, over time, it may requirerecalibration for various reasons. For example, the vehicle model mayrequire recalibration when replacement and/or repair of any part ofmachine 10 is performed. Worksite management system 38 may storepreconfigured calibration needs of machine 10, and may schedule theoccurrence of the calibration needs and their calibration.

In some embodiments, worksite management system 38 may coordinate withand/or otherwise control one or more machines 42 to make modificationsto road geometry, road conditions, and/or other aspects of worksite 11in order to assist in calibrating various vehicle models. Machines 42may be semi-autonomous or non-autonomous. In such cases, for example,worksite management system 38 may provide the operator ofsemi-autonomous and/or non-autonomous machines 42 with recommendedroutes and/or actions that semi-autonomous and/or non-autonomousmachines 42 may take to assist in the modification of worksite 11. Suchrecommended routes and/or actions may be presented to the operator via amonitor or other electronic display. FIG. 2 illustrates an exemplarymachine 42 that may be used to assist in making such modifications toworksite 11. Machine 42 may embody an earth moving machine such as adozer having a blade or other work tool 48 movable by way of one or moremotors or actuators 50. Machine 42 may also include one more tractiondevices 52 which may function to steer and/or propel machine 42. Machine42 may be directed by worksite management system 38 to perform a taskrelated to the preparation of a calibration site 40. For example, suchtasks may include a dozing operation, a grading operation, a levelingoperation, a bulk material removal operation, and/or any other type ofoperation that results in alteration of the current geography and/orroad conditions at calibration site 40.

As illustrated in FIG. 2, a control system 46 associated with machine 42may include on-board components that interact to affect operation ofmachine 42 in response to instructions received from worksite managementsystem 38 and/or positional information received from one or moresatellites 44. In particular, control system 46 may include a powersource 54 used to power actuators 50 and traction devices 52, a locatingdevice 56, a tool position sensor 58, and/or an on-board controller 60.On-board controller 60 may be in communication with power source 54,actuators 50, traction devices 52, locating device 56, and/or positionsensor 58 via multiple different communication links (not shown) toautonomously control operations of machine 42.

Power source 54 may include an engine such as, for example, a dieselengine, a gasoline engine, a gaseous fuel powered engine such as anatural gas engine, or any other type of engine apparent to one skilledin the art. Power source 54 may alternatively include a non-combustionsource of power such as a fuel cell, a power storage device, an electricmotor, or other similar mechanism. Power source 54 may be connected totraction devices 52 and/or actuators 50 via a direct mechanicalcoupling, an electric circuit, a hydraulic circuit, or in any othersuitable manner.

Locating device 56 may embody an electronic receiver configured tocommunicate with satellites 44 to determine a location of machine 42relative to satellites 44. In particular, locating device 56 may receiveand analyze high-frequency, low power radio signals from multiplesatellites 44 to triangulate a 3-D position relative to the differentsatellites 44. A signal indicative of this position may then becommunicated from locating device 56 to on-board controller 60.Alternatively, locating device 56 may embody an Inertial Reference Unit(IRU), a component of a local tracking system, or any other knownlocating device that receives and/or determines positional informationassociated with machine 42.

Position sensor 58 may embody any type of sensor configured to detect aposition of a work tool 48 relative to a known position on machine 42(for example, relative to locating device 56), and generate acorresponding signal. In one example, position sensor 58 may be anacoustic, magnetic, or optical-type sensor associated with actuators 50and/or one or more linkages that move work tool 48. In another example,position sensor 58 may be a local and/or global positioning sensorconfigured to communicate with off-board devices (for example, locallaser systems, radar systems, satellites, etc.) to directly determinelocal and/or global coordinates of work tool 48. It should be noted thatany number and/or type of position sensors 58 may be included andpositioned at any location on or near work tool 48. Based on signalsgenerated by position sensors 58 and based on known kinematics ofmachines 42, each on-board controller 60 may be configured to determine,in real time, a location of the associated work tool 48 relative to theknown position of machine 42 and communicate the location to on-boardcontroller 60 for further processing.

On-board controller 60 may include components configured to monitor,record, store, index, process, and/or communicate the location ofmachine 42 and position of work tool 48. In addition, such componentsmay be configured to automatically control operations of machine 42based on instructions received from worksite management system 38. Thesecomponents may include, for example, a memory, one or more data storagedevices, a central processing unit, or any other components that may beused to autonomously operate machine 42. Furthermore, although aspectsof the present disclosure may be described generally as being stored inmemory, one skilled in the art will appreciate that these aspects can bestored on or read from different types of computer program products orcomputer-readable media such as computer chips and secondary storagedevices, including hard disks, floppy disks, optical media, CD-ROM, orother forms of RAM or ROM. Such components may be similar to thosedescribed above with respect to on-board controller 20.

Tool controller 60 may further include components configured forcommunicating with worksite management system 38. For example, toolcontroller 60 may include hardware and/or software that enables sendingand receiving of data messages through a direct data link (not shown) ora wireless communication link (not shown). The wireless communicationsmay include satellite, cellular, infrared, and any other type ofwireless communications that enable on-board controller 60 to exchangeinformation with worksite management system 38.

Worksite management system 38, based on various user inputs and locationinformation from locating device 56 and position sensor 58, may beconfigured to execute instructions stored on computer readable medium toperform various methods of excavation planning and control for machines42. Such excavation planning methods may include, among other things,determining a required number, location, size, and/or shape of aplurality of cuts into an intended work surface 68 at calibration site40. Additional excavation planning methods may include grouping the cutsinto a plurality of spaced apart locations known as “slots,” determininga spacing between, a size of, and/or a trajectory of such slots, anddetermining a sequence of particular cuts that should be excavated inorder. Excavation planning methods may further include determining anumber of passes through each sequence required to accomplish anexcavation phase, and determining a number of phases required tocomplete an excavation plan. Worksite management system 38 may store inmemory various excavation plans for accomplishing modifications and/orconstruction of calibration site 40 for possible calibration-relatedneeds of machine 10.

Exemplary operation of worksite management system 38 is discussed belowwith reference to FIG. 3, FIG. 4 and FIG. 5.

INDUSTRIAL APPLICABILITY

The systems and methods of the present disclosure may be applicable toany mobile machine utilizing a vehicle model to control movement of themachine. Machine 10 may store in memory multiple vehicle modelscorresponding to different worksite conditions. For example, machine 10may store different vehicle models for dry road conditions, icy roadconditions, and wet road conditions. When the worksite conditions changeon worksite 11, the appropriate vehicle model may be calibrated and usedto control machine 10.

Machine 10 may also store in memory one or multiple vehicle modelscorresponding to different machine kinematics and/or dynamics, and oneor more such vehicle models may be calibrated during operation. Forexample, machine 10 may store different vehicle models for articulatedsteering, front and/or rear wheel steering, and/or skid steeringdynamics. During operation on the worksite 11, on-board controller 20may select the appropriate vehicle model based on which calibratedvehicle model most closely predicts vehicle operation, and the selectedvehicle model may be used to control machine 10.

In exemplary embodiments, the vehicle model used by machine 10 may beinitially calibrated, and subsequently recalibrated, after a period ofuse so when the vehicle model is used by on-board controller 20 thepredicted performance of machine 10 may be approximately equal to theactual performance of machine 10. If the predicted performance (forexample, the movements and/or activity) of machine 10 is substantiallysimilar to the actual performance of machine 10, then machine 10 willfunction efficiently within worksite 11.

FIG. 3 illustrates an exemplary method of how worksite management system38 may coordinate the calibration needs of machines 10 at worksite 11.Either worksite management system 38 or on-board controller 20 maymonitor operating conditions of machine 10, including various loads,operating states, orientations, and/or positions of machine 10, forwhich calibration has either not yet been completed or for which one ormore vehicle models associated with machine 10 require recalibration.

On-board controller 20 may identify when a need for calibration of anaspect of a vehicle model of machine 10 exists. In particular, atregular intervals, on-board controller 20 may use the vehicle model topredict a performance parameter of machine 10. Regular intervals mayinclude every few hours, every few months, or after machine 10 has beenin operation for a particular number of hours. At step 305, on-boardcontroller 20 may compare a measured performance of machine 10 to apredicted (predicted by the vehicle model) performance of machine 10. Inaddition to comparing measured and predicted performances at regularintervals, calibration-related needs of machine 10 may also bemonitored. Such needs may be monitored at similar intervals describedabove with regard to the vehicle model and may be monitored by sensors18 and 22. Examples of when calibration-related needs may arise mayinclude when wear of components on machine 10 is suspected, when aconfiguration of machine 10 is changed, or after machine 10 has beenrepaired. In each of these situations, machine 10 need not be sent to aspecialized testing facility or to a remote location relative toworksite 11 in order to update the vehicle model used by on-boardcontroller 20 to control machine 10. There may be opportunities tocalibrate the vehicle model by directing machine 10 to an appropriatecalibration site 40 within worksite 11.

At step 310, on-board controller 20 may determine if a measuredperformance parameter value of machine 10 is substantially equal to acorresponding predicted performance parameter value of machine 10.On-board controller 20 may make this determination by comparing datainput from sensors 18 and 22 with data supplied by the vehicle model.Sensors 18 and 22 may provide measured values indicative of and/orquantifying the aforementioned operating conditions of machine 10. Thevehicle model may provide predicted values corresponding to each of theoperating conditions. If the measured values are substantially equal tothe predicted values (Step 310—Yes), or if the difference between themdoes not exceed a threshold amount, machine 10 may continue to functionwith no identified need of calibration. The threshold amount may be anamount the actual performance of machine 10 is permitted to deviate fromthe predicted performance of machine 10 without requiring updating ofthe vehicle model. For example, the vehicle model may predict that basedon the load weight, speed, orientation, and other conditions for machine10, the expected stopping distance of machine 10 is 50 feet. The actualstopping distance for machine 10 under these conditions, however, may bemeasured by sensors 18, 22 as 54 feet. When the threshold amount is set,for example, to be a percentage of the predicted amount, such as 10%, orwhen the threshold is set to be a particular braking distance, such as 5feet, the difference between the predicted and actual performance ofmachine 10 does not exceed the threshold amount in the above example.Thus, in this example, machine 10 may continue to operate normally andefficiently without calibrating the vehicle model. As will be describedbelow, one or more mathematical expressions or equations may be derivedto account for the differences between the predicted and actualperformance values, and the vehicle model may be adjusted in view ofthese expressions or equations when the difference exceeds the thresholdamount.

If the measured values are not substantially equal to the predictedvalues (Step 310—No), and/or their difference is outside a predeterminedthreshold, on-board controller 20 may determine that the vehicle modelis in need of calibration, or recalibration. In particular, at step 320,on-board controller 20 may determine the calibration need andcommunicate the calibration need to worksite management system 38.

Once on-board controller 20 has identified a particular vehicle model asneeding to be calibrated, and a particular aspect of the vehicle modelhas been identified as needing to be calibrated, on-board controller 20may communicate this information to worksite management system 38 (step320) via an electronic signal and/or an otherwise wireless signal. Uponreceipt of the signal from on-board controller 20, worksite managementsystem 38 may search its memory for machine-specific templates.Machine-specific templates may include data associated with machineconditions, road conditions, and/or road geometries required for theaccurate calibration of the specific vehicle model related to theoperation of the particular machine 10. At step 325, worksite managementsystem 38 may search for the machine-specific template, identify thecalibration conditions required to calibrate a particular vehicle model,and may search a memory for a calibration site 40 where machine 10 mayperform the needed calibration. In particular, worksite managementsystem 38 may search a memory for a calibration site 40 that matches thecalibration need of machine 10. In such embodiments, data related to theroad conditions and geometries of worksite 11 may be stored within amemory of worksite management system 38. The data stored in the memorymay identify, among other things, the percent grade and distance of anincline in between various locations on worksite 11. The memory may alsostore data related to open, or otherwise undeveloped, areas ofautonomous worksite 11 where new roads and/or calibration sites 40 maybe constructed. At step 325, worksite management system 38 may evaluatethe available calibration sites 40 by quantifying each, based on theircharacteristics, and identifying a match where the difference betweenthe compared values falls within a predetermined range. The numericvalue of an available calibration site 40 may be referred to as asuitability index. Worksite management system 38 may identify whichcalibration sites 40 have suitability indices that fall within thepredetermined range. Quantifying a calibration need and/or a calibrationsite 40 may include assigning numerical values to variouscharacteristics. In this way, the closeness of a match involvingmultiple characteristics may be gauged by a calculated percent. Forexample, a 95% match between a calibration requirement and thesuitability index of a calibration site 40 may be deemed to be adequateand may be recognized by worksite management system 38 as a candidatematch that may be pursued. If a number of candidate calibration sites 40fall within the predetermined threshold (having a percent match of atleast 95% for the present example) worksite management system 38 mayautomatically select the candidate calibration site 40 with the highest,or closest, match.

At step 330, worksite management system 38 may determine if acalibration site 40 matching the calibration need of machine 10 existswithin worksite 11. If worksite management system 38 determines that acalibration site 40 matching the calibration need of machine 10 doesexist (Step 330—Yes) within worksite 11, then worksite management system38 may direct machine 10 to the matching calibration site 40 forcalibration (Step 340). Worksite management system 38 may direct machine10 to perforin the required calibration multiple times so as to confirmthat the calibration was performed correctly.

To calibrate the vehicle model at step 340, the actual performancevalues of machine 10 for the variety of loads, states, and conditionsmay be compared to the corresponding performance values predicted by theuncalibrated vehicle model, and the uncalibrated vehicle model may beadjusted based on results of those comparisons. Autonomously calibratingan aspect of the vehicle model may include adjusting a parameter valueassociated with the aspect of the vehicle model to be approximatelyequal to a corresponding value associated with an actual performance ofthe machine. For example, during the calibration process machine 10 maybe loaded to a certain weight, and with a certain load distribution, andmay be directed to proceed relatively straight (for example, at asteering angle of about 0 degrees) on a relatively flat surface (forexample, such that the roll and pitch of the machine are each about 0degrees). Braking distance may then be measured under these conditions.For each speed at which the actual braking distance of machine 10 isdetermined (measured by sensors 18, 22), the uncalibrated vehicle modelmay be used to predict a corresponding braking distance based on thesame load weight and distribution, steering angle, orientation, and thelike. Comparisons of the actual and predicted braking distance valuesmay be made, such as by on-board controller 20 or another processor. Thevehicle model may be adjusted or calibrated based on results of thecomparisons, such that the braking distances predicted by using thevehicle model may be substantially equal to the actual braking distancesas measured by sensors 18, 22. For example, one or more mathematicalexpressions or equations may be derived to account for differencesbetween expected and actual values. Similar comparisons may be made forvarious other combinations of conditions under which the actualperformance of machine 10 is determined, so that the calibrated vehiclemodel may accurately predict the performance of machine 10 on worksite11, including at loads, states, and conditions under which machine 10was not directly tested.

In exemplary embodiments, it may be necessary or desired that worksitemanagement system 38 direct machine 10 to multiple calibration sites 40within worksite 11 in order to address each of the road geometry androad condition-related calibration needs of machine 10. In suchembodiments, worksite management system 38 may generate a calibrationplan or “calibration roadmap” designating a route by which machine 10may visit one or more calibration sites 40 within worksite 11. Worksitemanagement system 38 may consider a number of different variables whencreating a calibration roadmap for machine 10. For example, worksitemanagement system 38 may account for the time of day, and the trafficcongestion that is characteristic of any particular time of day, andplan the calibration routes to be as time efficient as possible byavoiding high traffic areas and other potential points of concern atworksite 11. Additionally, worksite management system 38 may identifycandidate calibration paths that are near a normal travel route ofmachine 10. A normal travel route of machine 10 may include a route thatmachine 10 would ordinarily take in attending to its assigned worktasks.

With continued reference to FIG. 3, if a suitable calibration site 40cannot be identified by worksite management system 38 (Step 330—No)worksite management system 38 may proceed to step 350. At step 350,worksite management system 38 may determine whether a site withinworksite 11 would match the calibration need of machine 10 if relativelyminor modifications were made to the site. In particular, worksitemanagement system 38 may determine if worksite 11 includes a calibrationsite 40 having a characteristic corresponding to an aspect of thevehicle model in need of calibration, and that calibration of the aspectof the vehicle model requires modifying the characteristic ofcalibration site 40. Identifying such a potential site may follow asimilar process to that of Step 330 where the process of matchingcalibration needs with available potential calibration sites 40 involvesquantifying each, based on their characteristics, and identifying amatch where the difference between the compared values falls within apredetermined range. Alternatively, a candidate site for modificationmay be identified by its percentage match with the outstandingcalibration need of machine 10. Matches which result in quantitativevalues outside the predetermined range may be assumed to requiremodifications that are not relatively minor.

If such a candidate calibration site 40 is identified (Step 350—Yes),various conditions and/or geometries of the road and/or terrain at theselected candidate calibration site may be modified. For example, atstep 360, worksite management system 38 may direct one or more machines42 to make necessary modifications to the selected candidate calibrationsite so the selected candidate calibration site matches the calibrationneed of machine 10. In particular, worksite management system 38 mayidentify the one or more aspects of the vehicle model on the particularmachine 10 in need of calibration. Based on the identified aspects,worksite management system 38 may direct one or more machines 42 tocreate/modify conditions at the selected site so that the identifiedaspects of the vehicle model can be calibrated at the selected site. Insuch embodiments, machines 42 may be configured to modify various roadgeometries that may include curvatures, banks, grades, slaloms, roadwidths, and lane changes. Machines 42 may also be configured to modifyvariations of road conditions that may include dry, semi-wet, wet, verywet, icy, gravelly, and bumpy. One or more machines 42 may be dispatchedand controlled by worksite management system 38 to make the requiredmodifications in road geometry and condition at the selected calibrationcandidate site. Worksite management system 38 may coordinate multiplemachines 42 working simultaneously at the same calibration site 40.After the selected candidate calibration site is modified, worksitemanagement system 38 may direct machine 10 to the modified site forcalibration of the vehicle model (Step 365).

Machines 42 may also load machines 10 when the calibration needs ofmachines 10 further include a load condition. Worksite management system38 may direct machines 42 to load machines 10 with a load correspondingto the load condition prior to directing machines 10 to calibration site40.

If a suitable candidate site for modification is not identified (Step350—No), worksite management system 38 may proceed to step 370 whereworksite management system 38 may determine if space exists withinworksite 11 for construction of a site matching the calibration needs ofmachine 10. If such a space is found (Step 370—Yes), similar to Step360, worksite management system 38 may direct machines 42 to theselected space to construct (as opposed to modify an existingcalibration site 40 as in Step 360) a site matching the calibration needof machine 10 (Step 380). At step 380, one or more machines 42 may bedispatched and controlled by worksite management system 38 to constructthe customized calibration site 40 with the road geometries andconditions required for calibration of the vehicle model. In exemplaryembodiments, construction of a new calibration site 40 may be similar tothe process described above with respect to step 360. Worksitemanagement system 38 may direct machines 42 to construct a calibrationsite that matches the calibration need of machine 10 (Step 380). At step385, worksite management system 38 may direct machine 10 to the newlyconstructed calibration site 40 for calibration of the vehicle model.

If an open space does not exist within worksite 11 for construction of asite matching the calibration needs of machine 10 (Step 370—No),worksite management system 38 may log the data regarding the calibrationneed in memory for reassessment at a later time (Step 390). The loggeddata may be stored for use when additional space at worksite 11 becomesavailable. For example, when worksite 11 expands, or a previously neededcalibration site 40 is no longer needed, worksite management system 38may revisit the logged data and reassess the opportunity to modify anexisting calibration site 40, or to create a new calibration site 40 tomatch the calibration needs of machine 10. In the meantime, worksitemanagement system 38 may reassign machine 10 to a new work task thatdoes not require a work operation corresponding to the aspect of thevehicle model in need of calibration (Step 395). In an alternateembodiment, worksite management system 38 may modify how machine 10 isallowed to operate. For example, if a needed calibration relates to aparticular travel speed of machine 10 worksite management system maylimit the travel speed of machine 10 such that machine 10 will not reachthe particular travel speed for which calibration is required. In thisway, rather than reassign machine 10 to a new work task, machine 10 maybe able to continue performing its original work task within thelimitations established by worksite management system 38.

FIG. 4 illustrates another exemplary method of how worksite managementsystem 38 may coordinate the calibration needs of machine 10 at worksite11. In the exemplary method of FIG. 4, machine 10 may be programmed toautomatically alert worksite management system 38 as to when acalibration and/or recalibration need exists. Additionally, machine 10may be programmed to alert worksite management system 38 as to whichcalibration needs exist at which times. Steps 425 to 495 of FIG. 4 maybe identical to the analogous steps 325 to 395 of FIG. 3.

The calibration needs of machine 10, and all data related to thecalibration needs of machine 10, may be stored in a memory within, orassociated with, on-board controller 20. On-board controller 20 maycommunicate the calibration needs related to machine 10 to worksitemanagement system 38 via a signal.

Once on-board controller 20 has identified a particular vehicle model asneeding to be calibrated, and a particular aspect of the vehicle modelhas been identified as needing to be calibrated, on-board controller 20may communicate this information to worksite management system 38 (step420) via an electronic signal and/or an otherwise wireless signal. Uponreceipt of the signal from on-board controller 20, worksite managementsystem 38 may search its memory for machine-specific templates.Machine-specific templates may include data associated with machineconditions, road conditions, and/or road geometries required for theaccurate calibration of the specific vehicle model related to theoperation of the particular machine 10. At step 425, worksite managementsystem 38 may search for the machine-specific template, identify thecalibration conditions required to calibrate a particular vehicle model,and may search a memory for a calibration site 40 where machine 10 mayperform the needed calibration. In particular, worksite managementsystem 38 may search a memory for a calibration site 40 that matches thecalibration need of machine 10. In such embodiments, data related to theroad conditions and geometries of worksite 11 may be stored within amemory of worksite management system 38. The data stored in the memorymay identify, among other things, the percent grade and distance of anincline in between various locations on worksite 11. The memory may alsostore data related to open, or otherwise undeveloped, areas of worksite11 where new roads and/or calibration sites 40 may be constructed. Atstep 425, worksite management system 38 may evaluate the availablecalibration sites 40 by quantifying each, based on theircharacteristics, and identifying a match where the difference betweenthe compared values falls within a predetermined range. The numericvalue of an available calibration site 40 may be referred to as asuitability index. Worksite management system 38 may identify whichcalibration sites 40 have suitability indices that fall within thepredetermined range. Quantifying a calibration need and/or a calibrationsite 40 may include assigning numerical values to variouscharacteristics. In this way, the closeness of a match involvingmultiple characteristics may be gauged by a calculated percent. Forexample, a 95% match between a calibration requirement and thesuitability index of a calibration site 40 may be deemed to be adequateand may be recognized by worksite management system 38 as a candidatematch that may be pursued. If a number of candidate calibration sites 40fall within the predetermined threshold (having a percent match of atleast 95% for the present example) worksite management system 38 mayautomatically select the candidate calibration site 40 with the highest,or closest, match.

At step 430, worksite management system 38 may determine if acalibration site 40 matching the calibration need of machine 10 existswithin worksite 11. If worksite management system 38 determines that acalibration site 40 matching the calibration need of machine 10 doesexist (Step 430—Yes) within worksite 11, then worksite management system38 may direct machine 10 to the matching calibration site 40 forcalibration (Step 440). Worksite management system 38 may direct machine10 to perform the required calibration multiple times so as to confirmthat the calibration was performed correctly.

To calibrate the vehicle model at step 440, the actual performancevalues of machine 10 for the variety of loads, states, and operatingconditions may be compared to the corresponding performance valuespredicted by the uncalibrated vehicle model, and the uncalibratedvehicle model may be adjusted based on results of those comparisons.Operating conditions of machine 10 may include a travel speed of themachine, a steering rate of the machine, a braking rate of the machine,a weight hauled by the machine, a weight distribution of a load hauledby the machine, an orientation of the machine, a geographical locationof the machine, and a heading of the machine. Autonomously calibratingan aspect of the vehicle model may include adjusting a parameter valueassociated with the aspect of the vehicle model to be approximatelyequal to a corresponding value associated with an actual performance ofthe machine. For example, during the calibration process machine 10 maybe loaded to a certain weight, and with a certain load distribution, andmay be directed to proceed relatively straight (for example, at asteering angle of about 0 degrees) on a relatively flat surface (forexample, such that the roll and pitch of the machine are each about 0degrees). Braking distance may then be measured under these conditions.For each speed at which the actual braking distance of machine 10 isdetermined (measured by sensors 18, 22), the uncalibrated vehicle modelmay be used to predict a corresponding braking distance based on thesame load weight and distribution, steering angle, orientation, and thelike. Comparisons of the actual and predicted braking distance valuesmay be made, such as by on-board controller 20 or another processor. Thevehicle model may be adjusted or calibrated based on results of thecomparisons, such that the braking distances predicted by using thevehicle model may be substantially equal to the actual braking distancesas measured by sensors 18, 22. For example, one or more mathematicalexpressions or equations may be derived to account for differencesbetween expected and actual values. Similar comparisons may be made forvarious other combinations of conditions under which the actualperformance of machine 10 is determined, so that the calibrated vehiclemodel may accurately predict the performance of machine 10 on worksite11, including at loads, states, and conditions under which machine 10was not directly tested.

In exemplary embodiments, it may be necessary or desired that worksitemanagement system 38 direct machine 10 to multiple calibration sites 40within worksite 11 in order to address each of the road geometry androad condition-related calibration needs of machine 10. In suchembodiments, worksite management system 38 may generate a calibrationplan or “calibration roadmap” designating a route by which machine 10may visit one or more calibration sites 40 within worksite 11. Worksitemanagement system 38 may consider a number of different variables whencreating a calibration roadmap for machine 10. For example, worksitemanagement system 38 may account for the time of day, and the trafficcongestion that is characteristic of any particular time of day, andplan the calibration routes to be as time efficient as possible byavoiding high traffic areas and other potential points of concern atworksite 11. Additionally, worksite management system 38 may identifycandidate calibration paths that are near a normal travel route ofmachine 10. A normal travel route of machine 10 may include a route thatmachine 10 would ordinarily take in attending to its assigned worktasks.

With continued reference to FIG. 4, if a suitable calibration site 40cannot be identified by worksite management system 38 (Step 430—No)worksite management system 38 may proceed to step 450. At step 450,worksite management system 38 may determine whether a site withinworksite 11 would match the calibration need of machine 10 if relativelyminor modifications were made to the site. In particular, worksitemanagement system 38 may determine if worksite 11 includes a calibrationsite 40 having a characteristic corresponding to an aspect of thevehicle model in need of calibration, and that calibration of the aspectof the vehicle model requires modifying the characteristic ofcalibration site 40. Identifying such a potential site may follow asimilar process to that of Step 430 where the process of matchingcalibration needs with available potential calibration sites 40 involvesquantifying each, based on their characteristics, and identifying amatch where the difference between the compared values falls within apredetermined range. Alternatively, a candidate site for modificationmay be identified by its percentage match with the outstandingcalibration need of machine 10. Matches which result in quantitativevalues outside the predetermined range may be assumed to requiremodifications that are not relatively minor.

If such a candidate calibration site 40 is identified (Step 450—Yes),various conditions and/or geometries of the road and/or terrain at theselected candidate calibration site may be modified. For example, atstep 460, worksite management system 38 may direct one or more machines42 to make necessary modifications to the selected candidate calibrationsite so the selected candidate calibration site matches the calibrationneed of machine 10. In particular, worksite management system 38 mayidentify the one or more aspects of the vehicle model on the particularmachine 10 in need of calibration. Based on the identified aspects,worksite management system 38 may direct one or more machines 42 tocreate/modify conditions at the selected site so that the identifiedaspects of the vehicle model can be calibrated at the selected site. Insuch embodiments, machines 42 may be configured to modify various roadgeometries that may include curvatures, banks, grades, slaloms, roadwidths, and lane changes. Machines 42 may also be configured to modifyvariations of road conditions that may include dry, semi-wet, wet, verywet, icy, gravelly, and bumpy. One or more machines 42 may be dispatchedand controlled by worksite management system 38 to make the requiredmodifications in road geometry and condition at the selected calibrationcandidate site. Worksite management system 38 may coordinate multiplemachines 42 working simultaneously at the same calibration site 40.After the selected candidate calibration site is modified, worksitemanagement system 38 may direct machine 10 to the modified site forcalibration of the vehicle model (Step 465).

Machines 42 may also load machines 10 when the calibration needs ofmachines 10 further include a load condition. Worksite management system38 may direct machines 42 to load machines 10 with a load correspondingto the load condition prior to directing machines 10 to calibration site40.

If a suitable candidate site for modification is not identified (Step450—No), worksite management system 38 may proceed to step 470 whereworksite management system 38 may determine if space exists withinworksite 11 for construction of a site matching the calibration needs ofmachine 10. If such a space is found (Step 470—Yes), similar to Step460, worksite management system 38 may direct machines 42 to theselected space to construct (as opposed to modify an existingcalibration site 40 as in Step 460) a site matching the calibration needof machine 10 (Step 480). At step 480, one or more machines 42 may bedispatched and controlled by worksite management system 38 to constructthe customized calibration site 40 with the road geometries andconditions required for calibration of the vehicle model. In exemplaryembodiments, construction of a new calibration site 40 may be similar tothe process described above with respect to step 460. Worksitemanagement system 38 may direct machines 42 to construct a calibrationsite that matches the calibration need of machine 10 (Step 480). At step485, worksite management system 38 may direct machine 10 to the newlyconstructed calibration site 40 for calibration of the vehicle model.

If an open space does not exist within worksite 11 for construction of asite matching the calibration needs of machine 10 (Step 470—No),worksite management system 38 may log the data regarding the calibrationneed in memory for reassessment at a later time (Step 490). The loggeddata may be stored for use when additional space at worksite 11 becomesavailable. For example, when worksite 11 expands, or a previously neededcalibration site 40 is no longer needed, worksite management system 38may revisit the logged data and reassess the opportunity to modify anexisting calibration site 40, or to create a new calibration site 40 tomatch the calibration needs of machine 10. In the meantime, worksitemanagement system 38 may reassign machine 10 to a new work task thatdoes not require a work operation corresponding to the aspect of thevehicle model in need of calibration (Step 495). In an alternateembodiment, worksite management system 38 may modify how machine 10 isallowed to operate. For example, if a needed calibration relates to aparticular travel speed of machine 10 worksite management system maylimit the travel speed of machine 10 such that it will not reach theparticular travel speed for which calibration is required. In this way,rather than reassign machine 10 to a new work task, machine 10 is ableto continue performing its original work task within the limitationsestablished by worksite management system 38.

FIG. 5 illustrates an exemplary worksite map 510 that worksitemanagement system 38 may generate. Worksite management system 38 maygenerate worksite map 510 as a function of the above-described memorysearching and data analyzing techniques, and may provide operatorsand/or managers of worksite 11 with recommendations as to where todirect machine 10 to perform a single calibration or multiplecalibrations. In particular, during step 325 in FIG. 3 and during step425 in FIG. 4, worksite management system 38 may search a memory forcalibration sites 40 within worksite 11 that match a calibration need,or a plurality of calibration needs, related to the vehicle model ofmachine 10. During step 325 and/or step 425, and using data storedwithin the memory, worksite management system 38 may generate worksitemap 510 which may display the results of the search performed byworksite management system 38 for calibration sites 40 that match thecalibration needs of the vehicle model of machine 10. Additionally,worksite map 510 may display recommendations as to which calibrationsites 40 would provide the most time and resource-efficient opportunityfor making the necessary vehicle model calibration.

Worksite map 510 may include a depiction of various haul roads 520and/or various zones within worksite 11. Such zones may include, forexample, a loading zone 530 and a dumping zone 540. Worksite map 510 mayillustrate, for example, loading zone 530, dumping zone 540, and/orother zones within worksite 11 being interconnected by one or more haulroads 520. Worksite map 510 may also include a recommended calibrationsite 560 (depicted by circles in FIG. 5) as well as a second recommendedcalibration site 565 (depicted by circles in FIG. 5). Recommendedcalibration site 560 may be associated with one calibration needassociated with the vehicle model of machine 10, whereas secondrecommended calibration site 565 may be associated with a secondcalibration need associated with the vehicle model of machine 10. In theexemplary embodiment, recommended calibration site 560 and secondrecommended calibration site 565 may differ so as to address differentcalibration needs, or they may share similar features and present anoperator and/or manager of worksite 11 with multiple options foraddressing the same calibration need. Worksite map 510 may also includeadditional recommended calibration sites if additional calibration needsrelated to machine 10 exist. Worksite map 510 may include one or morerecommended calibration sites and/or paths in need of modification 555(depicted by squares in FIG. 5). As described above, recommendedcalibration sites and/or paths in need of modification 555 may includeareas that would suffice as calibration sites 40 if modifications weremade to them. Recommended calibration sites and/or paths in need ofmodification 555 may include stretches of haul roads 520 in need ofrepair. As machines 10 traverse haul roads 520, and detect roadconditions via sensors 18 (S, M, L) and 22, machines 10 may alertworksite management system 38 as to instances of slippage or otherphenomena that may be indicative of a haul road 520 or calibration site40 in need of repair and/or modification. Worksite map 510 may furtherinclude one or more calibration exclusion zones 550 (depicted by theletter “x” in FIG. 5). Calibration exclusion zones 550 may include hightraffic areas, for example, an intersection or a work zone such as aloading or dumping area. Calibration exclusion zones 550 may alsoinclude stretches of haul roads 520 that may be dangerous for certainmachines 10 to traverse. Calibration exclusion zones 550 may be areaswithin worksite 11 that the operator selects and/or otherwiseidentifies. Further, calibration exclusion zones 550 may include areasthat are designated for the calibration of other aspects of othervehicle models for other machines 10. Worksite management system 38 mayidentify recommended calibration site 560, second recommendedcalibration site 565, recommended calibration site and/or path in needof modification 555, and calibration exclusion zones 550 based on realtime data, as well as landscape and/or road geometry-related data,related to worksite 11. Worksite map 510 may include any one of a numberof various topographical features 570 that may indicate various detailsof the landscape of worksite 11. For example, one topographical feature570 of worksite map 510 may indicate an elevation of a particular zoneor segment of haul road 520.

Worksite management system 38 may provide worksite map 510 to a managerof worksite 11 via an electronic or wireless signal, and worksite map510 may be displayed on a monitor or other medium. Worksite map 510 maybe color coded. Recommended calibration routes 580 may be identified asa first color. Recommended calibration sites and/or paths in need ofmodification 555 may be identified as a second color. Calibrationexclusion zones 550 may be identified as a third color. For example,rather than displaying circles, worksite management system 38 may depictrecommended calibration site 560 and second recommended calibration site565 as green colored segments on worksite map 510. Rather thandisplaying squares, worksite management system 38 may depict recommendedcalibration sites and/or paths in need of modification 555 as yellowcolored segments on worksite map 510. Rather than displaying the letter“x”, worksite management system 38 may depict calibration exclusionzones 550 as red colored segments on worksite map 510. Worksitemanagement system 38 may present all the options related to recommendedcalibration sites 560, 565, recommended calibration sites and/or pathsin need of modification 555, and calibration exclusion zones 550 to amanager of worksite 11. Once presented with all the aforedescribedoptions associated with a calibration need the manager of worksite 11may add additional information to worksite map 510. For example, if themanager is aware of areas within worksite 11 that should be avoided whenplanning a calibration route, and these calibration exclusion zones 550were not identified by worksite management system 38, the manager maymanually designate the areas as such on worksite map 510.

As previously described, worksite management system 38 may generate acalibration plan or “calibration roadmap” designating a recommendedcalibration route 580 by which machine 10 may efficiently visit one ormore calibration sites 40 within worksite 11 while circumventingcalibration exclusion zones 550. Recommended calibration site 560 andsecond recommended calibration site 565 may correspond to calibrationsites 40 as described above. As previously described, worksitemanagement system 38 may consider a number of different variables whengenerating recommended calibration route 580 for machine 10. Forexample, worksite management system 38 may account for the time of day,and the traffic congestion that may be characteristic of a particulartime of day, and plan calibration routes that take the least amount oftravel time by avoiding high traffic areas and other potential points ofconcern at worksite 11. The high traffic areas and other potentialpoints of concern at worksite 11 may be designated on worksite map 510as calibration exclusion zones 550. Additionally, worksite managementsystem 38 may plan recommended calibration route 580 to be near a normaltravel route of machine 10. A normal travel route of machine 10 mayinclude a route that machine 10 would ordinarily take in attending toits assigned work tasks.

In an exemplary embodiment, a manager and/or operator of worksite 11 mayselect a particular machine 10 and/or vehicle model on the displaymonitor, and worksite management system 38 may display a map of worksite11 illustrating, in real time, the calibration sites available forcalibration of the particular machine 10 and/or vehicle model. Worksitemanagement system 38 may also provide the manager a summary or list ofcalibration and/or time-sensitive maintenance needs of machine 10. Themanager may request from worksite management system 38 a proposedcalibration site and or path. Worksite management system 38 may thenillustrate available and proposed areas to meet the calibration needs ofthe particular machine 10 and/or vehicle model. Worksite managementsystem 38 may illustrate multiple calibration maps for a plurality ofvarious machines on the same display such that the manager may see anoverall summary of calibration occurring within worksite 11, in realtime.

Worksite management system 38 may simultaneously schedule and coordinatethe calibrations of a plurality of machines 10 with varying calibrationneeds. For example, worksite management system 38 may schedule thecalibration of a first machine 10 at a certain time, and may delay theneeded calibration of a second machine 10 to occur after the completionof the calibration of the first machine 10. The scheduling function ofworksite management system 38 may incorporate work task prioritization,traffic patterns, blasting, and other events and factors into thescheduling of calibration of different machines 10. Calibrationschedules generated by worksite management system 38 may be subject toapproval by a site manager.

Use of the disclosed worksite map 510 may provide numerous advantages tooperators and/or managers of worksite 11. For example, by identifyingrecommended calibration sites 560, calibration exclusion zones 550,recommended calibration sites and/or paths in need of modification 555,and/or recommended calibration routes 580, worksite management system 38provides recommendations to a worksite manager for proposed paths toaccomplish a needed calibration in a time efficient fashion.Additionally, worksite map 510 may enable machine 10 to expend less fuelthan perhaps would otherwise be required by limiting the distancemachine 10 is required to travel to calibrate its vehicle model, and bylimiting the amount of time machine 10 may be delayed in trafficcongestion.

Use of the disclosed calibration system to initially calibrate andsubsequently recalibrate the vehicle model may provide numerousadvantages. As discussed above, because calibration and recalibrationoccur on the worksite 11, delays associated with adjustment of thevehicle model at a calibration site removed from worksite 11 may beavoided. Further, the vehicle model of machine 10 may be more accuratelycalibrated and recalibrated as compared to known calibration processes,since machine 10 may be calibrated using actual conditions on worksite11.

Use of the disclosed worksite management system 38 to autonomouslycoordinate the modification of calibration sites 40 for calibration ofthe vehicle model may also provide numerous advantages. In addition toavoiding delays associated with conducting calibration at sites removedfrom worksite 11, worksite management system 38 may enable a moreefficient use of both time and resources by creating and/or modifyingcalibration sites 40 within worksite 11. In particular, worksitemanagement system 38 may facilitate the creation and/or modification ofcalibration sites 40 near work sites and travel routes of machines 10such that machines 10 are calibrated in a time and travel efficientmanner. Furthermore, by coordinating and performing modifications tocalibration sites 40 autonomously, the human resources required forcontrolling operation of worksite 11 may be reduced.

It will be apparent to those skilled in the art that variousmodifications and variations can be made to the vehicle modelcalibration processes of the present disclosure. Other embodiments ofthe described methods and systems will be apparent to those skilled inthe art from consideration of the specification and practice of thevehicle model calibration processes disclosed herein. It is intendedthat the specification and examples be considered as exemplary only,with a true scope of the disclosure being indicated by the followingclaims and their equivalents.

What is claimed is:
 1. A method of modifying a worksite for calibratinga vehicle model used to autonomously control a first machine on theworksite, the method comprising: determining, with a controllerassociated with the machine, that an aspect of the vehicle model is inneed of calibration; providing a signal, indicating that the aspect ofthe vehicle model is in need of calibration, from the controller to aworksite management system disposed remote from the first machine;determining, with the worksite management system, that the worksiteincludes a calibration site having a characteristic corresponding to theaspect of the vehicle model, including searching a memory storing dataassociated with the worksite and selecting the calibration site fromamong a plurality of locations at the worksite based on a suitabilityindex of the calibration site, and that calibrating the aspect of thevehicle model requires modifying the characteristic of the calibrationsite; directing, with the worksite management system, a second machineat the worksite to autonomously modify the characteristic of thecalibration site; and directing, with the worksite management system,the first machine to the modified calibration site for autonomouscalibration of the aspect of the vehicle model.
 2. The method accordingto claim 1, wherein the aspect of the vehicle model includes at leastone of a speed of the first machine, a steering angle of the firstmachine, a weight hauled by the first machine, a weight distribution ofa load hauled by the first machine, an orientation of the first machine,a geographical location of the first machine, and a heading of the firstmachine.
 3. The method according to claim 1, wherein selecting thecalibration site from among a plurality of locations at the worksitebased on a suitability index of the calibration site includes comparinga quantitative value representative of a calibration requirement withsuitability indices of each of the plurality of locations, andautomatically selecting the calibration site which most closely matchesthe quantitative value of the calibration requirement.
 4. The methodaccording to claim 1, wherein the characteristic includes at least oneof a curvature, a bank, a grade, a slalom, and a lane change, a wetcondition, a dry condition, an icy condition, a bumpy condition, and agravely condition, and wherein autonomously modifying the characteristicincludes at least one of a wetting operation, an icing operation, adozing operation, a grading operation, a leveling operation, and a bulkmaterial removal operation.
 5. The method according to claim 1, furtherincluding autonomously calibrating the aspect of the vehicle model atthe modified calibration site, wherein autonomously calibrating theaspect of the vehicle model includes adjusting a parameter valueassociated with the aspect of the vehicle model to be approximatelyequal to a corresponding value associated with an actual performance ofthe first machine.
 6. The method according to claim 1, further includingreceiving an additional signal from the first machine indicative of anadditional aspect of the vehicle model in need of calibration;determining, in response to receipt of the additional signal, that theworksite does not include a calibration site having a characteristiccorresponding to the additional aspect of the vehicle model; anddetermining, in response to determining that the worksite does notinclude a calibration site having the characteristic corresponding tothe additional aspect of the vehicle model, if a space exists within theworksite for constructing a calibration site having the characteristiccorresponding to the additional aspect of the vehicle model.
 7. Themethod according to claim 6, further including the worksite managementsystem logging data associated with the additional aspect of the vehiclemodel in a memory for reassessment, in response to determining that nospace exists within the worksite for constructing a calibration sitehaving the characteristic corresponding to the additional aspect of thevehicle model, and assigning the first machine to a work task notrequiring operation associated with the additional aspect of the vehiclemodel, in response to determining that no space exists within theworksite for constructing a calibration site having the characteristiccorresponding to the additional aspect of the vehicle model.
 8. Themethod according to claim 6, further including the worksite managementsystem autonomously directing the second machine to construct acalibration site having the characteristic corresponding to theadditional aspect of the vehicle model, in response to determining thatspace does exist within the worksite for constructing a calibration sitehaving the characteristic corresponding to the additional aspect of thevehicle model.
 9. A system configured to modify a worksite forcalibrating a vehicle model used to autonomously control a first machineon the worksite, the system comprising: a controller disposed on thefirst machine, the controller configured to determine if an aspect ofthe vehicle model is in need of calibration, and to generate a signalindicative of an aspect of the vehicle model in need of calibration; anda worksite management system disposed remote from the first machine andin communication with the controller, the worksite management systemconfigured to determine, in response to receipt of the signal, whetherthe worksite includes a calibration site having a characteristiccorresponding to the aspect of the vehicle model, including searching amemory storing data associated with the worksite and selecting thecalibration site from among a plurality of locations at the worksitebased on a suitability index of the calibration site, and thatcalibrating the aspect of the vehicle model requires modifying thecharacteristic of the calibration site, wherein the worksite managementsystem is also configured to direct a second machine at the worksite toautonomously modify the characteristic of the calibration site, anddirect the first machine to the modified calibration site for autonomouscalibration of the aspect of the vehicle model.